Depression of the vestibulo-ocular and optokinetic responses by intrafloccular microinjection of GABA-A and GABA-B agonists in the rabbit

The functional implication of the cerebellar flocculus in regulation of the VOR and OKR gain has mostly been studied by lesion experiments, and the hypotheses derived from these experiments are not always in line with one another. In the present study, a reversible method was used to inhibit floccular Purkinje cells. The GABA-A agonist muscimol or the GABA-B agonist baclofen were bilaterally injected into the flocculus of rabbits, and the effects of these injections on the gain of the VOR and OKR were studied. Both drugs induced a reduction by at least 50% of the gain of the VOR in light and darkness, and of the OKR. Although GABA-A and GABA-B receptors are known to have different cerebellar localizations, muscimol and baclofen injections resulted in quantitatively similar effects. It is suggested that these GABA-agonists cause either direct or indirect inhibition of floccular Purkinje cells, thus reducing modulation of the firing rate of these neurons by afferent mossy and climbing fibers. Because the flocular Purkinje cells act out of phase with the vestibular neurons which drive the oculomotor neurons, a reduced output of floccular Purkinje cells would result in a reduction of the VOR and OKR gain. These experiments provide strong evidence that the cerebellar flocculus has a positive influence on the basic VOR and OKR gain.     

A New Approach for Determining Phase Response Curves Reveals that Purkinje Cells Can Act as Perfect Integrators

Cerebellar Purkinje cells display complex intrinsic dynamics. They fire spontaneously, exhibit bistability, and via mutual network interactions are involved in the generation of high frequency oscillations and travelling waves of activity. To probe the dynamical properties of Purkinje cells we measured their phase response curves (PRCs). PRCs quantify the change in spike phase caused by a stimulus as a function of its temporal position within the interspike interval, and are widely used to predict neuronal responses to more complex stimulus patterns. Significant variability in the interspike interval during spontaneous firing can lead to PRCs with a low signal-to-noise ratio, requiring averaging over thousands of trials. We show using electrophysiological experiments and simulations that the PRC calculated in the traditional way by sampling the interspike interval with brief current pulses is biased. We introduce a corrected approach for calculating PRCs which eliminates this bias. Using our new approach, we show that Purkinje cell PRCs change qualitatively depending on the firing frequency of the cell. At high firing rates, Purkinje cells exhibit single-peaked, or monophasic PRCs. Surprisingly, at low firing rates, Purkinje cell PRCs are largely independent of phase, resembling PRCs of ideal non-leaky integrate-and-fire neurons. These results indicate that Purkinje cells can act as perfect integrators at low firing rates, and that the integration mode of Purkinje cells depends on their firing rate.     

A simple model of delay,block and one way conduction in Purkinje fibers

Summary A simple qualitative model of the cardiac Purkinje fiber is introduced for the purpose of numerical simulation of experiments on conduction of the cardiac impulse. Well known approximation techniques are used to illustrate the behavior of the model membrane in the cases of space clamp and propagation of traveling pulses in a uniform infinite fiber. The results of the numerical simulations are then presented, and shown to be comparable to experiment.     

On the Firing Rate Dependency of the Phase Response Curve of Rat Purkinje Neurons In Vitro

Synchronous spiking during cerebellar tasks has been observed across Purkinje cells: however, little is known about the intrinsic cellular mechanisms responsible for its initiation, cessation and stability. The Phase Response Curve (PRC), a simple input-output characterization of single cells, can provide insights into individual and collective properties of neurons and networks, by quantifying the impact of an infinitesimal depolarizing current pulse on the time of occurrence of subsequent action potentials, while a neuron is firing tonically. Recently, the PRC theory applied to cerebellar Purkinje cells revealed that these behave as phase-independent integrators at low firing rates, and switch to a phase-dependent mode at high rates. Given the implications for computation and information processing in the cerebellum and the possible role of synchrony in the communication with its post-synaptic targets, we further explored the firing rate dependency of the PRC in Purkinje cells. We isolated key factors for the experimental estimation of the PRC and developed a closed-loop approach to reliably compute the PRC across diverse firing rates in the same cell. Our results show unambiguously that the PRC of individual Purkinje cells is firing rate dependent and that it smoothly transitions from phase independent integrator to a phase dependent mode. Using computational models we show that neither channel noise nor a realistic cell morphology are responsible for the rate dependent shift in the phase response curve.     

Neurotrophin-3 induced by tri-iodothyronine in cerebellar granule cells promotes Purkinje cell differentiation [published erratum appears in J Cell Biol 1998 Dec 28;143(7):following 2090]

Thyroid hormones play an important role in brain development, but the mechanism(s) by which triiodothyronine (T3) mediates neuronal differentiation is poorly understood. Here we demonstrate that T3 regulates the neurotrophic factor, neurotrophin-3 (NT-3), in developing rat cerebellar granule cells both in cell culture and in vivo. In situ hybridization experiments showed that developing Purkinje cells do not express NT-3 mRNA but do express trkC, the putative neuronal receptor for NT-3. Addition of recombinant NT-3 to cerebellar cultures from embryonic rat brain induces hypertrophy and neurite sprouting of Purkinje cells, and upregulates the mRNA encoding the calcium-binding protein, calbindin-28 kD. The present study demonstrates a novel interaction between cerebellar granule neurons and developing Purkinje cells in which NT-3 induced by T3 in the granule cells promotes Purkinje cell differentiation.     

Sprouting of adult Purkinje cell axons in lesioned mouse cerebellum: “Non-permissive” versus “permissive” environment

Adult rat Purkinje cells are extremely resistant to axotomy and, although they lack spontaneous regeneration, are able to sprout. Axon sprouting is a late process that occurs mainly 6 to 18 months after the lesion and results from an interplay between Purkinje cell intrinsic properties and chemical remodeling of the glial scar. To better appraise the role of the local environment in the late sprouting, we performed new axotomy experiments in mice. In this species, unlike the rat, there is no cavitation because the post-lesional necrotic tissue is invaded by astrocytes and incorporated into the glial scar. In this scarring tissue, chondroitin sulfate proteoglycans (CS-PGs) and PSA-NCAM are present one week after the lesion, but the time courses of their expression differ: the former are transiently expressed and rapidly disappears (by one month), thus preventing early sprouting and providing a negative spatiotemporal correlation with the late sprouting. PSA-NCAM expression, which is maintained up till 12 months, is by itself not sufficient to attract the sprouts, since the core of the glial scar—which exhibits high level of PSA-NCAM—is always devoid of them. Finally, by using a double experimental approach (lesion and graft) aimed at providing a permissive environment to the terminal bulbs of axotomized Purkinje cells, we show that the presence of grafted cerebellum at the lesion site neither changes the time course of the sprouting nor enhances the Purkinje cell axonal regeneration. Nevertheless, these experiments have revealed a new type of altered Purkinje cells, the “irritated” Purkinje cells with a high potentiality for axon sprouting.     

Mathematical simulation of induction of long-term depression in cerebellar Purkinje cells

Mechanisms of associative and homosynaptic long-term depression (LTD) in cerebellar Purkinje cells are discussed. The possibility of LTD induction related to a decrease in efficacy of AMPA receptors through either their dephosphorylation or phosphorylation is investigated by mathematical simulation.     

Cdk5 activity is required for Purkinje cell dendritic growth in cell‐autonomous and non‐cell‐autonomous manners

Cyclin‐dependent kinase 5 (Cdk5) is recognized as a unique member among other Cdks due to its versatile roles in many biochemical processes in the nervous system. The proper development of neuronal dendrites is required for the formation of complex neural networks providing the physiological basis of various neuronal functions. We previously reported that sparse dendrites were observed on cultured Cdk5‐null Purkinje cells and Purkinje cells in Wnt1^cre‐mediated Cdk5 conditional knockout (KO) mice. In the present study, we generated L7^cre‐mediated p35; p39 double KO (L7^cre‐p35^f/f; p39^–/–) mice whose Cdk5 activity was eliminated specifically in Purkinje cells of the developing cerebellum. Consequently, these mice exhibited defective Purkinje cell migration, motor coordination deficiency and a Purkinje dendritic abnormality similar to what we have observed before, suggesting that dendritic growth of Purkinje cells was cell‐autonomous in vivo . We found that mixed and overlay cultures of WT cerebellar cells rescued the dendritic deficits in Cdk5‐null Purkinje cells, however, indicating that Purkinje cell dendritic development was also supported by non‐cell‐autonomous factors. We then again rescued these abnormalities in vitro by applying exogenous brain‐derived neurotrophic factor (BDNF). Based on the results from culture experiments, we attempted to rescue the developmental defects of Purkinje cells in L7^cre‐p35^f/f; p39^–/– mice by using a TrkB agonist. We observed partial rescue of morphological defects of dendritic structures of Purkinje cells. These results suggest that Cdk5 activity is required for Purkinje cell dendritic growth in cell‐autonomous and non‐cell‐autonomous manners. © 2017 Wiley Periodicals, Inc. Develop Neurobiol 77: 1175–1187, 2017     

The Reelin receptors Apoer2 and Vldlr coordinate the patterning of Purkinje cell topography in the developing mouse cerebellum

The adult cerebellar cortex is comprised of reproducible arrays of transverse zones and parasagittal stripes of Purkinje cells. Adult stripes are created through the perinatal rostrocaudal dispersion of embryonic Purkinje cell clusters, triggered by signaling through the Reelin pathway. Reelin is secreted by neurons in the external granular layer and deep cerebellar nuclei and binds to two high affinity extracellular receptors on Purkinje cells-the Very low density lipoprotein receptor (Vldlr) and apolipoprotein E receptor 2 (Apoer2). In mice null for either Reelin or double null for Vldlr and Apoer2, Purkinje cell clusters fail to disperse. Here we report that animals null for either Vldlr or Apoer2 individually, exhibit specific and parasagittally-restricted Purkinje cell ectopias. For example, in mice lacking Apoer2 function immunostaining reveals ectopic Purkinje cells that are largely restricted to the zebrin II-immunonegative population of the anterior vermis. In contrast, mice null for Vldlr have a much larger population of ectopic Purkinje cells that includes members from both the zebrin II-immunonegative and -immunopositive phenotypes. HSP25 immunoreactivity reveals that in Vldlr null animals a large portion of zebrin II-immunopositive ectopic cells are probably destined to become stripes in the central zone (lobules VI-VII). A small population of ectopic zebrin II-immunonegative Purkinje cells is also observed in animals heterozygous for both receptors (Apoer2(+/-): Vldlr(+/-)), but no ectopia is present in mice heterozygous for either receptor alone. These results indicate that Apoer2 and Vldlr coordinate the dispersal of distinct, but overlapping subsets of Purkinje cells in the developing cerebellum.     

The Analysis of Purkinje Cell Dendritic Morphology in Organotypic Slice Cultures

Purkinje cells are an attractive model system for studying dendritic development, because they have an impressive dendritic tree which is strictly oriented in the sagittal plane and develops mostly in the postnatal period in small rodents ³. Furthermore, several antibodies are available which selectively and intensively label Purkinje cells including all processes, with anti-Calbindin D28K being the most widely used. For viewing of dendrites in living cells, mice expressing EGFP selectively in Purkinje cells ¹¹ are available through Jackson labs. Organotypic cerebellar slice cultures cells allow easy experimental manipulation of Purkinje cell dendritic development because most of the dendritic expansion of the Purkinje cell dendritic tree is actually taking place during the culture period ⁴. We present here a short, reliable and easy protocol for viewing and analyzing the dendritic morphology of Purkinje cells grown in organotypic cerebellar slice cultures. For many purposes, a quantitative evaluation of the Purkinje cell dendritic tree is desirable. We focus here on two parameters, dendritic tree size and branch point numbers, which can be rapidly and easily determined from anti-calbindin stained cerebellar slice cultures. These two parameters yield a reliable and sensitive measure of changes of the Purkinje cell dendritic tree. Using the example of treatments with the protein kinase C (PKC) activator PMA and the metabotropic glutamate receptor 1 (mGluR1) we demonstrate how differences in the dendritic development are visualized and quantitatively assessed. The combination of the presence of an extensive dendritic tree, selective and intense immunostaining methods, organotypic slice cultures which cover the period of dendritic growth and a mouse model with Purkinje cell specific EGFP expression make Purkinje cells a powerful model system for revealing the mechanisms of dendritic development.     

Cumulative effects of alcohol (ethanol) on the activity of Purkinje cells in the cat cerebellum

The effects of three consecutive injections of 2 ml/kg 30% alcohol (ethanol, i.v.) on the activity of identified cerebellar Purkinje cells were investigated during experiments on adult cats anesthetized by a Nembutal-chloralose mixture. It was found that repeated alcohol injections exert a cumulative effect on the firing rate of these cells. The alcohol-induced rise in Purkinje cell firing rate, produced by excitation of the mossy fibers, was generally accompanied by a reduction in that of cells responding to excitation of climbing fibers. The inhibitory pause occurring after complex discharges in cerebellar Purkinje cells grew shorter with successive alcohol injections.I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 19, No. 1, pp. 74–80, January–February, 1987.     

Purkinje neurons: What is the signal for complex spikes?

Cerebellar Purkinje neurons generate characteristic complex spikes; but are these bursts of activity generated by somatic or dendritic excitability? A recent study may have settled this debate by giving the soma the dominant role, but it does not fully resolve the question of what information is transmitted downstream of the Purkinje cells.     

Gene transfer into Purkinje cells using herpesviral amplicon vectors in cerebellar cultures

Purkinje cells play a crucial role in sensory motor coordination since they are the only output projection neurons in the cerebellar cortex and are affected in most spinocerebellar ataxias. They stand out in the central nervous system due to their large size and their profusely branched dendritic arbor. However, molecular and cellular studies on Purkinje cells are often hampered by the difficulty of maintaining these cells in culture. Here we report an easy, robust and reproducible method to obtain Purkinje-enriched mixed cerebellar cell cultures from day 16 mouse embryos using papain digestion and a semi-defined culture medium, being the composition of the culture approximately 20% Purkinje cells, 70% non-Purkinje neurons and 10% glial cells. We demonstrate that efficient gene transfer into Purkinje cells (as well as into other cerebellar populations) is possible using herpes simplex virus-1 (HSV-1)-derived vectors. Indeed, up to 50% of the Purkinje cells can be transduced and gene expression may persist for at least 14 days. As a result, this procedure permits functional gene expression studies to be carried out on cultured Purkinje neurons. To demonstrate this, we show that the expression of a dominant-negative form of glycogen synthase kinase-3 protects Purkinje neurons against cell death triggered by a chemical inhibitor of phosphatidylinositol-3 kinase. In summary, we have established reproducible and reliable cerebellar cell cultures enriched for Purkinje cells which enables gene transfer studies to be carried out using herpesviral vectors.     

Impaired calcium release in cerebellar Purkinje neurons maintained in culture

Cerebellar Purkinje neurons demonstrate a form of synaptic plasticity that, in acutely prepared brain slices, has been shown to require calcium release from the intracellular calcium stores through inositol trisphosphate (InsP(3)) receptors. Similar studies performed in cultured Purkinje cells, however, find little evidence for the involvement of InsP(3) receptors. To address this discrepancy, the properties of InsP(3)- and caffeine-evoked calcium release in cultured Purkinje cells were directly examined. Photorelease of InsP(3) (up to 100 microM) from its photolabile caged analogue produced no change in calcium levels in 70% of cultured Purkinje cells. In the few cells where a calcium increase was detected, the response was very small and slow to peak. In contrast, the same concentration of InsP(3) resulted in large and rapidly rising calcium responses in all acutely dissociated Purkinje cells tested. Similar to InsP(3), caffeine also had little effect on calcium levels in cultured Purkinje cells, yet evoked large calcium transients in all acutely dissociated Purkinje cells tested. The results demonstrate that calcium release from intracellular calcium stores is severely impaired in Purkinje cells when they are maintained in culture. Our findings suggest that cultured Purkinje cells are an unfaithful experimental model for the study of the role of calcium release in the induction of cerebellar long term depression.     

Formals for histogram analysis of Purkinje cell interspike intervals

A hypothesis has been advanced proposing that the resting discharge of Purkinje cells depends on two factors: 1) tonic excitatory inflow and 2) Puasson's inhibitory inflow. This is why variety of interspike intervals is supposed to be the result of non-regular arrival of inhibitory impulses. From these assumptions an analytical expression was derived allowing to calculate probabilities of interspike intervals of various durations. The histograms of interspike intervals obtained analitically were found to coincide satisfactory with those obtained in experiments (Fig. 3, a, b). The analysis of real histograms based on the presented theory allowed to compare excitatory and inhibitory inflows to individual Purkinje Cells. It was found that, on the average, those cells which had large excitatory inflow, had also large inhibitory one, and vice versa (Fig. 4). It was also found that small decrease (about 20 percent) of excitatory inflow, or corresponding increase of inhibitory inflow, resulted in complete inhibition of most Purkinje cells.     

Maturation of the activity of cerebellar Purkinje cells and the lift reaction

In experiments on guinea pigs (from newborn to adults), studies have been made on the extensor, support and lift reactions, as well as on the activity of cerebellar Purkinje cells in the same animals. First signs of immature lift, extensor and support reactions were observed already 12th after birth. At this period, mean discharge frequency in Purkinje cells was significantly lower than in the adult animals, reaching 11.5 +/- 1.2 imp/s for simple spikes and 0.45 +/- 0.05 imp/s for complex ones. Complete maturation of lift, extensor and support reactions takes place to the beginning of the 2nd week (8-9 days) of postnatal life. Within this period, significant changes in the activity of Purkinje cells were observed: mean discharge frequency of simple and complex spikes increased correspondingly up to 17.9 +/- 2.3 and 1.48 +/- 0.25 imp/s. At the same time, the mean discharge frequency in Purkinje cells, the average duration of inhibition pause, and the response latency became more stable.     

Localizing Genes to Cerebellar Layers by Classifying ISH Images

Gene expression controls how the brain develops and functions. Understanding control processes in the brain is particularly hard since they involve numerous types of neurons and glia, and very little is known about which genes are expressed in which cells and brain layers. Here we describe an approach to detect genes whose expression is primarily localized to a specific brain layer and apply it to the mouse cerebellum. We learn typical spatial patterns of expression from a few markers that are known to be localized to specific layers, and use these patterns to predict localization for new genes. We analyze images of in-situ hybridization (ISH) experiments, which we represent using histograms of local binary patterns (LBP) and train image classifiers and gene classifiers for four layers of the cerebellum: the Purkinje, granular, molecular and white matter layer. On held-out data, the layer classifiers achieve accuracy above 94% (AUC) by representing each image at multiple scales and by combining multiple image scores into a single gene-level decision. When applied to the full mouse genome, the classifiers predict specific layer localization for hundreds of new genes in the Purkinje and granular layers. Many genes localized to the Purkinje layer are likely to be expressed in astrocytes, and many others are involved in lipid metabolism, possibly due to the unusual size of Purkinje cells.     

Inhibition of GABAergic Transmission as a Model of Hyperactivation of Purkinje Cells in the Rat Cerebellum

Biophysics - Abstract—Pathological changes in the cerebellum are often associated with dysfunction of Purkinje cells, which is manifested in excessive spike activity. In our experiments, the...     

小脑浦肯野细胞动作电位传输保真度在大鼠出生后发育期间的变化

小脑浦肯野细胞的轴突是小脑皮层唯一的传出通路,研究其动作电位传输能力对于了解小脑的生理功能具有重要意义.大鼠在出生后第2周到第3周,小脑浦肯野细胞的形态及功能都有显著变化,产生动作电位的能力明显增强.而轴突上动作电位传输能力的变化还有待研究.运用胞体以及轴突的双电极膜片钳技术,研究了出生8天以及15天的Wistar大鼠小脑浦肯野细胞轴突上动作电位的传输.与8天组相比,15天组大鼠小脑浦肯野细胞轴突上动作电位的传输能力明显增强.后超极化可以增强8天组轴突上动作电位的传输能力.研究表明,随着发育的成熟,动作电位的产生能力以及轴突上动作电位的传输能力同步增强.     

Light and dark Purkinje cells (light microscopic and microautoradiographic studies]

The authors deal with the phenomenon of dualism of pale and dark ganglion cells in general, the phenomenon which, since FLEMMING (1882), still remains an actual problem of neurohistology. They deal with Purkinje cells from a special aspect with the aim to demonstrate the dualism through various staining methods. They directed their attention also to the question of the influence of perfusion and immersion fixation and length of staining with luxol-fast-blue on the production of luxol-positive (chromophilic) Purkinje cells. The authors have found that these methodologic circumstances do not influence the production of luxol-positive Purkinje cells, so it can be hardly spoken about an artifact. Examinations with the labelled leucine have shown that the increased metabolic activity can be observed in those Purkinje cells which in HE-picture are seen as pale ones. In the dark Purkinje cells leucine granulations are located on the surface of plasmatic membrane and they follow to some distance the main dendrite of those cells. The microautoradiographic method evidences for the increased leucine metabolism of the pale Purkinje cells as well.